1964–1968: Planning and start of construction Before the PSB became operational in 1972, the protons were directly delivered to the
Proton Synchrotron (PS) by the linear accelerator
Linac 1, providing the PS with protons of 50 MeV, which were then accelerated by the PS to 25 GeV at beam intensities of approximately 1012 protons per pulse. However, with the development of new experiments (mainly at the
Intersecting Storage Rings ISR), the demanded beam intensities in the order of 1013 protons per pulse exceeded the capabilities of this setup. Therefore, different approaches on how to increase the beam energy already before the protons enter the PS were discussed. Different suggestions for this new PS injector were made, for example another linear accelerator or five intersecting synchrotron rings inspired by the shape of the
Olympic rings. Eventually, it was decided to go for a setup of four vertically stacked
synchrotron rings with a radius of 25 meters, which was proposed in 1964. With this special design, it would become possible to reach the aspired intensities of more than 1013 protons per pulse. In 1967, the budget of the overall update program was estimated to be 69.5 million CHF (1968 prices). More than half of this sum was devoted to the construction of the PSB, which started one year later, in 1968. Construction of
Linac 2 started in December 1973 and was completed in 1978.
Linac 1 continued to operate as a source of light ions up to 1992.
1988: Upgrade to 1 GeV After more than ten years of operation, the constant increase of the beam intensity also demanded an increase in output energy of the PSB. Therefore, with only minor hardware adjustments, the PSB was upgraded to 1 GeV in 1988.
1980s–2003: Accelerating ions From the beginning of the 1980s until 2003, the PSB was also used to accelerate light ions like
oxygen or
alpha-particles, which were delivered by
Linac 1. After
Linac 3 as a dedicated ion linear accelerator became operational, also heavy ions such as
lead and
indium were accelerated by the PSB. From 2006 on, the
Low Energy Ion Ring (LEIR) took over PSB's former task of accelerating ions.
1992: Connection to ISOLDE experiment Up to 1992, the only machine that used the output protons from the PSB was the PS. This changed in 1992, when the
On-Line Isotope Mass Separator (ISOLDE) became the second recipient of PSB's protons. Before, ISOLDE had obtained protons from the
Synchro-Cyclotron, but this machine had reached the end of its lifetime by the end of the 1980s. Thus, it was decided in 1989 to connect ISOLDE to the PSB.
1999: Preparation for the LHC and upgrade to 1.4 GeV With the
Large Hadron Collider (LHC) at the horizon, another upgrade of the PSB to 1.4 GeV was necessary. This upgrade implied more severe adjustments of the hardware than the previous upgrade to 1 GeV, because the limits of PSB's design parameters had been reached. In 2000, the upgrade was completed.
2010–2026: Future upgrades for the High Luminosity Large Hadron Collider In 2010, the cornerstone for another upgrade of the LHC was laid: the
High Luminosity Large Hadron Collider. The much higher required beam intensity made it necessary to increase the PSB's output energy to 2.0 GeV. This was implemented during Long Shutdown 2 (2019–2020) by the exchange and update of various key equipment of the PSB, for example the main power supply, the radio-frequency system, the transfer line to the PS and the cooling system. Additionally, the input energy of the PSB has been increased:
Linac4, provides an output beam energy of 160 MeV, replacing
Linac2. Linac4 enables the PSB to provide higher quality beam for the LHC by using
hydrogen anions (H− ions) rather than bare protons (H+ ions). A stripping foil at the PSB injection point will strip the electrons off the hydrogen anions, thus creating protons that are accumulated as beam bunches in the four PSB rings. These proton bunches are then recombined at the exit of the PSB and further transferred down the CERN injector chain. ==Setup and operation==